DE3246930A1 - Switching a load over from an electrical mains power supply to a power supply unit - Google Patents

Abstract

While a load (4) is being switched over, without any interruption, from an electrical mains power supply (3) to a power supply unit which has an energy store (20) and a converter (1) which is controlled via a drive unit (triggering unit) (14), a first switching element (S1) between the main power supply (3) and the load (4), and a second switching element (S2) between the load (4) and the converter (1), as well as the converter (1) itself, are intended to be controlled or regulated in such a manner that no voltage dips or spikes occur. Once the converter (1) has been synchronised to the mains power supply (3) and the converter output voltage has been matched to the mains power supply voltage, before switching over, the reference variable for a voltage regulator (12) for the converter (1) is increased while switching over is taking place, that is to say during the time in which the two switching elements are kept closed in an overlapping manner, and the voltage regulator itself is made to have more inertia. A comparator (7) is used to determine when the converter (1) has taken over the entire current for the load (4) in order then to isolate the load (4) from the mains power supply (3), using the first switching element (S1). <IMAGE>

Description

Switching a consumer from an electrical one

Network on a power supply unit Description The invention relates refer to a method for uninterrupted switching of a consumer according to the preamble of claim 1 and. to an arrangement for the implementation of the procedure. Such a method and a circuit arrangement designed accordingly are known from DE-AS 17 65 270.

An uninterrupted switchover of a consumer from an electrical one Mains to a power supply unit or vice versa is particularly in the case of uninterruptible Power supply systems required. A block diagram for an example of one uninterruptible power supply system is shown in FIG. One with AC voltage Consumer 4 to be supplied is by closing a first switching element S1 connected to an electrical (AC) network. Can the network 3 from any Reasons do not provide energy for the consumer 4, this is through Close a second switching element S2 to a power supply unit violin. This consists of an energy storage device (battery 20) and an inverter working converter 1, which the DC voltage provided by the battery converted into the alternating voltage required by the consumer 4. The energy storage 20 becomes at times when the grid can supply energy via a rectifier 21 loaded.

To an uninterrupted supply of the consumer 4 when switching from network 3 to the power supply unit or vice versa is to be ensured it is necessary to switch the two switching elements for one to keep them closed together for a certain period of time.

While when switching the consumer from the power supply unit on the stable network usually no problems arise with the Switching the consumer from the mains to the power supply unit Problems due to voltage drops in converter 1 or

due to an overshoot of current and voltage.

To avoid the voltage drops and surges when switching over In practice, longer overlap times are fixed for the two switching elements provided as well as transition resistors and transition chokes in the converter circuit has been switched on. Despite the relatively large effort, it has been shown that the measures, which are difficult to adjust and test anyway, are only for one certain operating conditions are satisfactory.

The invention is based on the object while reducing the effort an interruption-free and bumpless switchover of the consumer on components from the mains to the power supply unit.

According to the invention, this object is achieved for the initially specified Method achieved by the features characterized in claim 1.

As a result of the increase in the specified reference variable for the converter and making its voltage regulator support is advantageously achieved that the converter slowly but steadily takes over load current and No voltage drops at the moment of switching (i.e. when the second switching element is opened) and peaks occur.

Advantageous embodiments of the method according to the invention are characterized in claims 2 and 3. Because the overlap time of the both switching elements is determined depending on the current, it is guaranteed in any case, that the consumer is not disconnected from the network prematurely.

Advantageous arrangements for performing the method according to Invention are characterized in claims 4 and 5.

The invention is intended in the following with reference to the drawing for an embodiment explained. 2 shows a basic circuit diagram of a switching device according to the invention, Fig. 3 voltage and current curves and switch positions of the two switching elements during a switchover of a previously known type and Fig. 4 current and voltage curves as well as the positions of the switching elements during the process the invention.

As already described for FIG. 1, according to FIG. 2, the consumer 4 with the closed switching element Sl from the electrical network 3, the one or can also be three-phase, fed. The consumer 4 can also by closing of the switching element S2 to the power supply unit, of which in Fig. 2 only the working as an inverter power converter 1 with its power unit 22 and its Control unit 2 is shown to be connected. For uninterrupted Power supply of the consumer 4 must be ensured that it is connected to one of the both energy sources is connected and that if the one supplying it fails Source an uninterrupted switchover via the two switching elements S1 and S2 takes place.

When the consumer 4 is fed from the power supply unit via converter 1 (i.e. switching element S2 closed, switching element S1 open) the control unit 2 takes over the control of the converter valves (not shown) built-up power section 22 in inverter operation. To this end, the Control unit 2 has a voltage regulator 12. An actual value preparation 19 in the voltage regulator 12, the output voltage of the power section 22 is fed as a control variable. the An encoder 17 provides the reference variable for voltage regulation. The exit of the encoder 17 and the output of the actual value processing 19 are for the setpoint-actual value comparison placed at a point 18, from which the control deviation is fed to a control amplifier 15 is. The control amplifier 15 gives its output signal to a control set 14, the provides the control pulses for the converter valves in power unit 22. The clock signals for the control set 14 are also from the output voltage of the power section 22 fed oscillator 13 specified. The voltage regulator 12 furthermore has a current limiter 16 which, on the input side, is connected to a first, primary side connected to the current converter 9 through which the current flows through the converter is. The current limitation 16 acts on the control amplifier 15 in such a way that a voltage adjustment the power section 22 is only made so far that a maximum current through the Converter is not exceeded.

If the operating case is that the consumer 4 with its busbar 11 with closed switching element S1 (and open switching element S2) on the electrical Network 3 is and should be an uninterrupted switchover of the consumer 4 the power supply unit (converter 1) take place, it is desirable that at overlapping closing of the switching element S2 and opening of the switching element S1 none Voltage dips or surges on the converter 1 occur. According to the invention the switching elements S1 and 52 as well as the converter 1 are controlled or regulated that the desired uninterrupted and bumpless switchover of the consumer 4 from the network 3 to the converter 1 is ensured. The voltage deviation the mains voltage of the nominal value and the internal resistance of the network are irrelevant.

Before switching the consumer 4 from the network 3 to the converter 1 is the latter by a frequency and phase controller 5, the oscillator 13 influenced accordingly, synchronized with the network. With the help of a controller 6 the converter output voltage is matched to the mains voltage. Then the second switching element S2 -closed, while the first switching element S1 also remains closed. During the switchover, i.e. during the The time in which both switching elements S 1 and S2 are closed, there is an increase the reference variable of the voltage regulator 12.

The switching time is also during this overlap phase Switching elements S1 and S2 of the voltage regulator 12 made more sluggish, which has the consequence that the converter 1 slowly but steadily takes over load current.

The increase in the reference variable for the voltage regulator and its carrier-making are done by switching on additional resistors at the encoder 17 for the reference variable or in the Feedback of the control amplifier 15. For switching on these resistances for the entire time in which the switching elements S1 and S2 are closed are provided by an AND element, which is connected on the input side to the two switching elements S1 and S2 is in communication. A comparator 7 determines when the Converter 1 has taken over the entire current for the consumer 4, so that then the latter can be separated from the network 3 by opening the first switching element S1. The inputs of the comparator 7 are for this purpose with the secondary sides both of the first current transformer 9 through which the current flows through the converter 1 on the primary side as well as a second, through which the consumer 4 flows on the primary side Current transformer 10 connected. If the two currents are equal, the comparator gives 7 an opening signal to the first switching element S1 between consumer and mains away.

Switching over is activated by opening the switching element 51 when the current is equal completed. The increase in the reference variable of the voltage regulator 12 is withdrawn and the controller resumes its original state, which corresponds to the converter dynamics Timing a.

As a result of the current comparison via the comparator 7, the overlap time is for the closed switching elements S1 and S2 depending on the current and thus over time so variable that it is always ensured that the converter 1 actually supplies the entire current for the consumer 4.

This is also made clear by comparing the currents and voltages, those in Fig. 3 for the prior art and Fig. 4 for the method according to the invention are juxtaposed.

It can be seen that the line current i3 when switching on the second Switching element S2 begins to decrease, while the current i1 through the converter 1 slowly increases begins to flow. While in the prior art (Fig. 3) the current i4 and the load voltage u4 when the first switching element S1 opens after a fixed time show clear overshoot, this is in the method according to the invention (Fig. 4) excluded because the first switching element S1 is only opened when the currents i1 and i4 are equal, i.e. the network current i3 has become zero.

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Claims (5)

Switching a consumer from an electrical network to on Power supply unit claims 1 i method for uninterruptible Switching a consumer from. an electrical network to a power supply unit, an energy store and a power converter controlled by a tax rate having, wherein first the converter has a frequency and phase regulator and synchronized with the control rate applied by a voltage regulator and is kept in sync and whereupon a first switching element between the Network and the consumer is only opened after a second switching element between the consumer and the power supply unit have been closed for a while has been characterized in that during the time the consumer via the two closed switching elements both through the network as well as being fed by the power supply unit, the voltage regulator of the Converter made sluggish and the reference variable given to it is increased. 2. The method according to claim 1, characterized in that determined is when the converter has taken over all the electricity for the consumer, in order to then disconnect the consumer from the mains by opening the first switching element. 3. The method according to claim 2, characterized in that the determination when the converter has taken over all of the current by comparing between the current through the converter and the current through the consumer is taken. 4. Arrangement for performing the method according to one of the claims 1 to 3, characterized in that each of the two switching elements (S1, S2) with the input of an AND element (8) is connected, the output side with a transmitter (17) for the reference variable and a control amplifier (15) of the voltage regulator (12) of the converter (1) is connected in such a way that only when the two are closed Switching elements (S1, S2) increase the reference variable in the encoder (17) and the control amplifier (15) is made carrier. 5. Arrangement according to claim 4 for performing one of the methods according to claim 2 or 3, characterized in that that both a first, Current transformer (9) through which the current flows through the converter (1) on the primary side and a second one, through which the consumer (4) flows on the primary side Current transformer (10) connected on the secondary side to the inputs of a comparator (7) are, when the two currents are equal, an opening signal to the switching element (S1) delivers between consumer (4) and network (3).